CH719047A2 - Discontinuous clockwork drive mechanism. - Google Patents

Abstract

The invention relates to a clockwork drive mechanism, comprising a driven mobile (10) and a driving mobile (12) intended to cooperate with the driven mobile (10) in a discontinuous manner, said driving mobile (12) comprising at least a drive member (120) arranged on or connected to at least one flexible element characterized in that the drive member (120) is capable of moving between: a first state in which the drive member (120 ) is located on a first trajectory defining a first penetration of the drive member (120) relative to the driven mobile (10), a second state, of actuation, in which the drive member (120) is located on a second trajectory defining a second penetration of the drive member with respect to the driven mobile (10), the second penetration being greater than the first penetration and in that the mechanism comprises a fixed support member (129) arranged to bring the drive member (120) into its second state, at least in a drive phase during which the driving mobile (12) is capable of driving the driven mobile (10).

Description

Technical area

The present invention relates to the field of watchmaking, in particular mechanical or electromechanical. It relates more particularly to a drive mechanism.

State of the art

[0002] Watch mechanisms are based, in particular, on the transmission of force by gears. If these elements are well known, the fact remains that their development is delicate, because the moving parts engaged must have a clearance to avoid clamping and other buttresses between the teeth, but ensuring that the race drive is efficient and the meshing is precise.

[0003] When the drive is discontinuous (progressive, semi-instantaneous or instantaneous), that is to say that a driven mobile is driven only at predefined intervals by a driving mobile, for example once a twenty-four hours for a date wheel which advances one step per day, care must be taken to ensure that the penetration of the teeth allows the driven wheel to be driven over a sufficient stroke and at the desired time. This is achieved by adjusting the penetration between the teeth of the mobiles. The penetration can be defined as being the length according to which the radii of the two mobiles overlap on the line of the centers.

[0004] The adjustment of the efficiency of the transmission on the one hand, and the adjustment of the moment at which it takes place on the other hand, oppose each other. Indeed, greater penetration (or stronger meshing) increases the stroke of the driven mobile, but decreases the safety of the system, by increasing the risk that the leading mobile drives the driven mobile too soon.

The present invention aims to provide a drive mechanism which avoids adjustment difficulties by ensuring both a drive with good penetration of the mobiles, without prejudice to safety.

Disclosure of Invention

More specifically, the invention relates to a clockwork drive mechanism, comprising a driven mobile and a driving mobile intended to cooperate with the driven mobile in a discontinuous manner, said driving mobile comprising at least one drive member drive arranged on or connected to at least one flexible element.

[0007] According to the invention, the drive member is capable of moving between: a. a first state in which the drive member is located on a first trajectory defining a first penetration of the drive member relative to the driven mobile, and b. a second state, actuation, in which the drive member is located on a second trajectory defining a second penetration of the drive member relative to the driven mobile, the second penetration being greater than the first penetration.

[0008] Furthermore, the mechanism comprises a fixed support member arranged to bring the drive member into its second state, at least in a drive phase during which the driving mobile is capable of driving the mobile led.

[0009] Preferably, the drive member is a tooth.

In a first embodiment, the tooth is connected to the mobile leading by at least two elastically deformable blades, arranged so that the tooth is essentially mobile in radial translation.

In a second embodiment, the tooth is connected to the mobile leading by at least one elastically deformable blade, arranged so that the tooth is essentially mobile according to a rotation.

[0012] The driving mobile may comprise an opening in which the fixed support member is seated.

[0013] Preferably, the driving mobile is of generally annular shape and is integral with a drive level.

Advantageously, the drive member is shaped by cutouts made in a board, said cutouts also defining the elastic blade or the elastic blades.

[0015] Advantageously, the edges of the cutout form support and guide members with which the drive member is capable of cooperating.

Advantageously, the position of the support member is adjustable.

[0017] According to another aspect, the invention also relates to a timepiece movement comprising a drive mechanism incorporating one or other of the preceding characteristics.

Brief description of the drawings

Other details of the invention will appear more clearly on reading the following description, made with reference to the appended drawing in which: Figure 1 is an isometric representation of a mechanism according to the invention, in its environment, FIG. 2 represents a detail view of a part of the mechanism of FIG. 1, and Figure 3 is an enlarged view of Figure 1, in which a bridge has been removed in order to better show the mechanism according to the invention.

Embodiment of the invention

There is shown in Figure 1 a clockwork drive mechanism, comprising a driven mobile 10 and a driving mobile 12 intended to cooperate with the driven mobile 10 in a discontinuous manner. By discontinuous cooperation, we express the fact that the two mobiles are not in a permanent meshing relationship, but that the kinematic connection between the two is only active at predetermined intervals, in principle regular, to drive the driven mobile 10 at specific instants or periods, depending on whether the training is instantaneous, on the one hand, or semi-dragging/dragging, on the other hand.

In the example particularly chosen to illustrate the invention, it is a date mechanism, in which the leading mobile 12 is typically driven at the rate of one revolution in 24 hours, to cooperate with the mobile conducted 10 once a day, around midnight. The driven mobile 10 is a wheel of 31, performing one revolution in 31 days. It is associated with a date indicator member, not visible in the figures. The invention is however not limited to the drive of a date, but can be adapted for any discontinuous drive, for example and in a non-exhaustive manner for a counter, for example of a chronograph, any indicator of a calendar, day, month, year or moon phases, or any digital disc indicators.

[0021] The driving wheel 12 comprises at least one drive member 120 arranged on at least one flexible element 122. In the preferred embodiment illustrated in the figures, it can be seen in particular in Figure 2 that the drive member drive 120 takes the form of a tooth or a finger, which is connected by flexible blades to a board 124, which is an element of the mobile drive 12. The latter comprises a drive level 126, or level input, by which it is itself driven by the watch movement, in the example at the rate of one revolution in 24 hours. In the case shown, the driving mobile 12 takes the form of a differential, and the board 124 is driven via satellites 128, connecting the board 124 to the drive level. This aspect of the illustrated timepiece, not forming the subject of the invention, will not be described in detail.

[0022] More specifically, the tooth comprises a driving part 1200, at a first end, intended to work more particularly with the driven mobile 10. The tooth also comprises a heel 1202, located at a second end opposite the first, in l species oriented towards the center of the mobile leading 12. The role of the heel 1202 will appear later.

The tooth is cut in the board 124, in a radial direction. The cutouts extend in a direction perpendicular to the tooth and define a pair of flexible, elastic blades, constituting the flexible element 122 and which symmetrically connect the tooth to the board 124. These blades ensure the mobility of the tooth in a radial direction. . Preferably, the elastic blades are of rectangular section.

[0024] The edges of the cutout form support and guide members which make it possible to ensure that the tooth moves essentially radially and to limit deformations during the transmission of a torque to the driven mobile 10. The board 124 can be laser cut, stamped, obtained by growth in a mold (LIGA) or engraved in a silicon plate, depending on the material chosen.

According to the invention, the drive member 120 is capable of moving between: a. a first state in which the drive member 120 is located on a first trajectory defining a first penetration of the drive member 120 with respect to the driven mobile 10, and b. a second state, of actuation, in which the drive member 120 is located on a second trajectory defining a second penetration of the drive member relative to the driven mobile 10, the second penetration being greater than the first penetration .

[0026] Preferably, the first state corresponds to a state of rest, in which the elastic blades which hold the mobile tooth are not constrained (the constraints linked to the mass of the tooth will be neglected). The first penetration which is obtained when the tooth is in its first state, is associated with a security which the person skilled in the art, that is to say the watchmaker, defines as being sufficient. By way of illustration, it is generally considered that a security of 0.1 mm is satisfactory. However, this must be adapted according to the specific case, the mechanisms and the manufacturing tolerances of the parts considered.

The second state corresponds to a stressed state, in which the movable tooth is brought to protrude relative to the first state, by constraining the elastic blades. The second penetration which is obtained when the tooth is in its second state, is associated with a training stroke which the person skilled in the art defines as sufficient. In other words, the drive part 1200 penetrates between two adjacent teeth of the driven mobile, respectively the tooth referenced 1000 which will be pushed by the drive member, and the tooth referenced 1002, the tip of which can be seen slightly (fig 3). The end of the driving part 1200 is located on a trajectory determined by the construction, so that it moves at a safe distance, but as close as possible to the profile of the tooth 1002, in other words with an optimized clearance and as low as possible.

[0028] To bring the drive member 120 into its second state, the mechanism comprises a fixed support member 129 arranged to cooperate with the heel 1202 and push the tooth, when the latter is facing the member support 129. Alternatively, the support member 129 can also be designated by the terms abutment or cam. Thus, the support member 129 is arranged to actuate the drive member, at least in a drive phase during which the driving mobile 12 is capable of driving the driven mobile 10. Once the drive done, the heel 1202 leaves the support member 129 and the tooth returns to its first state, under the elastic effect of the blades.

It is therefore understood that when the drive member 120 is in its second state, the penetration of the driving part 1200 into the teeth of the driven mobile 10 is greater than when it is in the first state.

[0030] The support member 129 is therefore dimensioned so as to be effective and to maintain the tooth in its second state, at an angle which corresponds substantially to a pitch of the driven mobile 10. In other words, preferably, the member support 129 fixed is effective on the drive member to bring it into its second state, only in the driving phase of the driven mobile 10 by the driving mobile 12. More specifically, the optimization of the shape and adjustment of the support member, as will be explained below, allow the mobile tooth to be brought into its second state only when it has passed the tip of the tooth 1002.

In the example, the support member 129 takes the form of a pin secured to a bridge 14, in reference to which the board 124 is rotatable. It is therefore understood that the bridge 14 is located in a different plane from the board 124, but that the pin is located at least partially in the plane of the board 124, to interact with the heel 1202 of the tooth when the stroke of the latter cross the pin.

[0032] The pin can advantageously be cylindrical or bevelled, in order to present a profile capable of providing a sliding surface to the heel 1202, avoiding any blockage. It is also possible to arrange the support member 129 eccentrically on the frame, in order to be able to adjust the penetration of the second state, as well as the moment at which the support member begins to act on the drive member. To do this, either the pin is cylindrical and pivotally mounted eccentrically, or the pin is elliptical in shape and pivotally mounted, centrically or eccentrically. Alternatively, it is also possible to adjust the position of the support member 129 with means for moving the bridge 14, or a part of the bridge which carries the pin. This part of the bridge can be moved by elastic deformation, via an adjustment screw resting on a fixed part of the bridge 14.

[0033] The adjustment possibilities of the support member are not in contradiction with the fact that it is fixed. In operation, the support member is fixed, after the adjustment has been made beforehand.

By bearing against the bearing member 129, during the rotation of the board 124, the tooth is pushed radially. In other words, drive member 120 is brought into its second state. The support provided by the support member 129 and the edges of the cutout of the board 124, allow the tine to have an effective driving action, without suffering from its assembly on elastic blades.

In this example and in the other applications mentioned above, the drive member 120 only passes in the race of the driven mobile 10 when a drive must actually be performed. In fact, there is no programming to take into account and the support member 129 can be fixed. For the same reason, when the drive member 120 is in the first state, it can go beyond the circumference of the vertices of the driven mobile 10, or indifferently not be on a trajectory which crosses this circumference. The solution proposed by the invention is therefore both particularly simple and effective.

[0036] It is possible to envisage various alternatives to the example particularly described, without however departing from the scope of the invention defined in claim 1. For example, the board 124 in which the drive tooth is formed can simply be integral with a wheel, directly driven by the movement, without implementing a differential. The tine can also be integrated in the thickness of the drive level, in a mobile with two levels.

[0037] In an additional variant, the tooth could be rotatable, connecting it by a single elastic blade to the board 124. The rotation is then essentially centered on the point of attachment of the elastic blade.

In general, the shape of the elastic blade or elastic blades can be adapted using finite element calculations and digital simulations to optimize the operation of the mechanism according to the invention. Other shapes than the one described above are thus possible, for example: with variable sections, continuously over the length of the blade, or discontinuous over this length with one or more thickenings, with curved or meander-like shapes, by modifying the number of blades, as required, it is also possible to have an asymmetrical distribution of the number of blades on either side of the tooth.

It is also possible to envisage an inverted mounting with a drive member 120 acting in the direction of the center of rotation of the leading mobile 12. The drive member 120 can, for example, be mounted on a ring and be able to drive a wheel located inside the ring, defining the driven mobile.

The board 124 may comprise several drive members, optionally adjacent or integral with each other, for example by having a common heel 1202 cooperating with the support member 129, connected by the same elastic blades. In the latter case, the support member 129 can occupy an angle substantially equal to n pitch of the driven mobile 10, if the board 124 comprises n integral drive members.

[0041] It is also possible to combine several support members, for example to actuate one or more drive members so that they drive several driven mobiles. For example, a 24-hour wheel can drive a 31 wheel on the one hand and a moon phase indicator on the other. It is also possible to arrange in superposition several drive mechanisms according to the invention, or only several driving mobiles, the respective drive member of which is actuated by a single or more support member(s).

Claims (10)

1. Clockwork drive mechanism, comprising a driven mobile (10) and a driving mobile (12) intended to cooperate with the driven mobile (10) in a discontinuous manner, said driving mobile (12) comprising at least one member of drive (120) arranged on or connected to at least one flexible element (122), characterized in that the drive member (120) is capable of moving between: ¿ a first state in which the drive member (120) is located on a first trajectory defining a first penetration of the drive member (120) relative to the driven mobile (10), ¿ a second state, actuation, in which the drive member (120) is located on a second trajectory defining a second penetration of the drive member relative to the driven mobile (10), the second penetration being superior to first penetration and in that the mechanism comprises a fixed support member (129) arranged to bring the drive member (120) into its second state, at least in a drive phase during which the driving wheel set (12 ) is capable of driving the driven mobile (10). 2. Drive mechanism according to claim 1, characterized in that the drive member (120) is a tooth. 3. Drive mechanism according to claim 2, characterized in that said tooth is connected to the driving wheel set (12) by at least two elastically deformable blades, arranged so that the tooth is essentially movable according to a radial translation. 4. Drive mechanism according to claim 2, characterized in that said tooth is connected to the driving wheel set (12) by at least one elastically deformable blade, arranged so that the tooth is essentially movable according to a rotation. 5. Drive mechanism according to one of the preceding claims, characterized in that the driving wheel set (12) comprises an opening in which the fixed support member (129) takes place. 6. Drive mechanism according to claim 5, characterized in that the driving wheel set (12) is of generally annular shape and in that it is integral with a drive level. 7. Drive mechanism according to one of claims 3 to 6, characterized in that the drive member (120) is shaped by cutouts made in a board (124), said cutouts also defining the elastic blade in the dependence of claim 4 or the spring blades in the dependence of claim 3. 8. Drive mechanism according to claim 7, characterized in that the edges of the cutout form support and guide members with which the drive member (120) is adapted to cooperate. 9. Drive mechanism according to one of the preceding claims, characterized in that the position of the support member is adjustable. 10. Clock movement comprising a drive mechanism according to one of claims 1 to 9.